Wireless Power Supply System and Wireless Power Supply Method

ABSTRACT

An object is to provide a system for improving convenience for users, by which a portable electronic device or the like can be charged even in a place where utility power is not available. Another object is to provide a system which allows a service provider to easily perform customer management. A wireless power supply system includes a power storage device having a power storage portion, a terminal charging device for wirelessly supplying electric power to the power storage device, and a management server having user information. Electric power can be supplied to specified users by intercommunication of user information between the power storage device and the terminal charging device and between the terminal charging device and the management server.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a system for charging a power storagedevice. The present invention specifically relates to a wireless powersupply system and a wireless power supply method for charging a powerstorage device using electric waves.

2. Description of the Related Art

At various scenes of social life, the processing of information througha computer network is performed, and the realization of a ubiquitoussociety where convenience of the processing of information through acomputer network can be enjoyed is approaching. The word “ubiquitous”comes from the Latin meaning “existing or being everywhere” (beingomnipresent) and is used in a sense that the processing of informationusing computers is naturally widespread throughout a living environmentwithout any awareness of computers at anytime or anywhere.

A portable electronic device such as a cellular phone requires a batterycharger for charging a built-in battery. Electric power that isnecessary for a charger is received from utility power distributed toeach house. In other words, in order to charge a built-in battery of aportable electronic device, the portable electronic device needs to beset in a battery charger and a power supply cord (plug) of the batterycharger needs to be plugged into an outlet. Accordingly, there isnormally a problem in that a charging operation for a portableelectronic device cannot be performed in a place where utility power isnot available. Therefore, in order to enable a charging operation for aportable electronic device even in a place where utility power is notavailable, a portable charging device is thought of, which is chargedwith externally supplied electric energy without contact, stores theelectric energy, and outputs the electric energy at the time of charging(for example, refer to Japanese Published Patent Application No.2003-299255).

SUMMARY OF THE INVENTION

However, a conventional portable charging device has a problem in thatan unspecified number of users can gain electric energy which issupplied from an external device if they have a means to receive theelectric energy. On the other hand, a service provider who intends tosupply charging electric power to specific customers has a desire tolimit who is to receive the supply of charging electric power.

Thus, it is an object of the present invention to provide a system forimproving convenience for users, by which a portable electronic deviceor the like can be charged even in a place where utility power is notavailable. It is another object to provide a system which allows aservice provider to easily perform customer management.

The subject matter of the present invention relates to a wireless powersupply system which includes a management server, a terminal chargingdevice connected to the management server via a communication line, anda power storage device that is charged by the terminal charging devicewithout contact.

The management server has a communication portion which transmits andreceives information to and from the terminal charging device, a firststorage medium which stores user identification information, and asecond storage medium which stores usage information of electric powercharging. The terminal charging device has a terminal communicationportion which communicates with the management server, a power signaltransmission portion which transmits electric power to the power storagedevice, a measuring portion which measures the amount of electric powersupplied to the power storage device, and an antenna which communicateswith the power storage device and transmits electric power to the powerstorage device. The power storage device has a memory portion whichstores identification information, an antenna which receiveselectromagnetic waves that are transmitted from the terminal chargingdevice, and a power storage portion which stores the electromagneticwaves that are received by the antenna as electric power.

When the power storage device which stores electric power generated fromelectric waves that are received from the terminal power storage devicehas the memory portion which stores identification information and theterminal charging device and the management server which have obtainedthe identification information cooperate with each other, a customer tobe served can be identified.

The subject matter of the present invention also relates to a wirelesspower supply method for managing power supply in a system which includesa management server including a storage medium storing useridentification information, a terminal charging device connected to themanagement server via a communication line, and a power storage deviceconfigured to be charged by the terminal charging device withoutcontact.

The wireless power supply method is a method including the steps of:reading identification information stored in a memory portion of thepower storage device, determining validity of the identificationinformation, and making the terminal charging device operate to supplyelectric power to an effective power storage device. By determination onthe identification information obtained from the power storage device inthe management server about whether or not to operate the terminalcharging device, a service can be provided for specific customers.

According to the present invention, a user can be identified, and apower storage device of the user can be charged. In this case, since anidentification number is stored in the power storage device andregistered with the management server in advance, a user does not needto perform any troublesome operation in charging. In addition,convenience for users can be increased because charging can be performedwithout contact and thus there is no need to carry around a heavy ACadaptor or secondary battery. On the other hand, a provider can offer aservice to specific customers so that the provider can meet customers'needs and can unify management of customer information such as billing.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram showing a structure of a wireless power supplysystem according to Embodiment Mode 1.

FIG. 2 is a diagram showing a structure of a wireless power supplysystem according to Embodiment Mode 2.

FIG. 3 is a flow chart showing an operation of the wireless power supplysystem according to Embodiment Mode 2.

FIG. 4 is a diagram showing an operation of the wireless power supplysystem according to Embodiment Mode 2.

FIG. 5 is a diagram showing an operation of the wireless power supplysystem according to Embodiment Mode 2.

FIG. 6 is a diagram showing a structure of a wireless power supplysystem according to Embodiment Mode 3.

FIG. 7 is a diagram showing an operation of the wireless power supplysystem according to Embodiment Mode 3.

FIG. 8 is a diagram showing an operation of the wireless power supplysystem according to Embodiment Mode 3.

FIG. 9 is a diagram showing a structure of a wireless power supplysystem according to Embodiment Mode 4.

FIG. 10 is a flow chart showing an operation of the wireless powersupply system according to Embodiment Mode 4.

FIGS. 11A and 11B are diagrams each showing an example of an applicationof a memory card with a power storage device.

FIGS. 12A to 12C are plan views each showing a structure of a powerstorage device according to Embodiment Mode 5.

FIGS. 13A and 13B are cross-sectional views each showing a structure ofthe power storage device according to Embodiment Mode 5.

FIGS. 14A to 14D are plan views each showing a structure of the powerstorage device according to Embodiment Mode 5.

FIGS. 15A and 15B are cross-sectional views each showing a structure ofthe power storage device according to Embodiment Mode 5.

FIG. 16 is a diagram showing a planar structure of a power storagedevice according to Embodiment Mode 6.

FIGS. 17A and 17B are cross-sectional views each showing a structure ofthe power storage device according to Embodiment Mode 6.

FIGS. 18A and 18B are diagrams each showing a mode in which the powerstorage device shown in FIGS. 17A and 17B is embedded in a living bodyor a solid for use.

DETAILED DESCRIPTION OF THE INVENTION

Embodiment modes of the present invention are hereinafter described withreference to the accompanying drawings. Note that the present inventioncan be carried out in many different modes, and it is to be easilyunderstood by those skilled in the art that the mode and details of thepresent invention can be variously changed without departing from itsspirit and scope. Therefore, the present invention should not beinterpreted as being limited to the description in the embodiment modes.Note that the same portions or portions having similar functions in thediagrams below are denoted by the same reference numerals, andrepetitive explanation thereof is omitted.

(Embodiment Mode 1)

This embodiment mode describes a wireless power supply system withreference to FIG. 1. This wireless power supply system has a powerstorage device 10 and a terminal charging device 12 as components. Theterminal charging device 12 may be connected to a management server 14.The power storage device 10 functions to store electric power and ischarged by receiving electric waves which are supplied from the terminalcharging device 12. The power storage device 10 can be carried around bya user. The power storage device 10 is present in a living space in adistributed manner by being carried around arbitrarily by a user. Thepower storage device 10 can be charged while within a range where it canreceive electric waves which are transmitted from the terminal chargingdevice 12.

One or more terminal charging devices 12 are prepared. The installationsite of the terminal charging device 12 may be determined inconsideration of convenience for a user of the power storage device 10.Because the range that the single terminal charging device 12 can coveris limited and affected by ambient environment, a certain area may becovered using a plurality of terminal charging devices 12. The terminalcharging device 12 may be installed either inside or outside of variousbuildings, such as train stations, bus stops, airports, other publicfacilities, commercial buildings, accommodation facilities, stores, andshopping malls. In addition, it may be installed in telephone poles,traffic lights, and cellular base stations.

The terminal charging device 12 is connected to a power supply network18 to supply electric power to the user of the power storage device 10.If the terminal charging device 12 is not connected to the power supplynetwork 18, it may be connected to a power generating system 19 thatuses natural energy such as sunlight, wind, or geothermal heat. By usingnatural energy, the terminal charging device 12 can be installed inmountain areas and remote areas where a power grid is not laid.

The amount of electric power consumed by the user of the power storagedevice 10 is managed by the management server 14. The management server14 has a communication function to transmit and receive information toand from the terminal charging device 12 and a function to store useridentification information and/or usage information of power charging.The management server 14 may be connected to the terminal chargingdevice 12 via a communication network 16 through which they canintercommunicate information. The communication network 16 may be adedicated communication line or a communication line using a utilitypower network as well as an information network such as a telephone lineor the Internet. Note that a plurality of management servers 14 may beconnected to the communication network 16. Preparation of the pluralityof management servers 14 allows for the use of this wireless powersupply system by a plurality of users at the same time.

In the wireless power supply system, the management server 14 and theterminal charging device 12 operate in cooperation with each other tosupply electric power to the power storage device 10. This wirelesspower supply system allows the user of the power storage device 10 toreceive a supply of power wirelessly at various locations in livingspace. A manager (service provider or the like) of the management server14 can manage the amount of electric power obtained by users through acommunication network and can estimate a demand by statisticalprocessing of usage as well as charge for usage and the like.

(Embodiment Mode 2)

The wireless power supply system of the present invention includes apower storage device which can be charged without contact, a terminaldevice which supplies electric power to the power storage device, and amanagement server which manages electric power that is supplied to thepower storage device. FIG. 2 shows one structural example of thewireless power supply system.

The power storage device 10 has a power storage portion 106 which storeselectric power. The power storage portion 106 stores electric powerobtained by rectification by a charging portion 104 of electric wavesreceived by an antenna 100. The power storage portion 106 is preferablyformed using a capacitor such as an electric double layer capacitor or aceramic capacitor. Because a capacitor can store electric power withoutchemical reaction, unlike a lead battery or a lithium-ion battery(secondary battery), it has advantages of a short charging time and nodeterioration due to repetitive charging and discharging. In addition,reductions in size and weight can be achieved.

The antenna 100 of the power storage device 10 receives a control signaland a power signal which are transmitted from the terminal chargingdevice 12. The control signal received by the antenna 100 is input to apower storage device communication portion 102. The power storage devicecommunication portion 102 outputs the control signal to a signal controlportion 103. The power signal received by the antenna 100 is input tothe power storage device communication portion 102, and the power signalis then output to the charging portion 104.

In the case where the terminal charging device 12 transmits a controlsignal or a power signal, by transmission of identification signalsbefore and after a carrier wave of the signal, the power storage devicecommunication portion 102 can easily distinguish the signal fromanother. As another method for easy distinction of the signal, amodulated wave obtained by superimposing a control signal on a powersignal may be used. As another method, the frequency band of a controlsignal and that of a power signal may be made to be different from eachother.

In any case, the power storage device 10 and the terminal chargingdevice 12 operate to transmit and receive signals to and from each otherby wireless communication. Types of control signals transmitted from theterminal charging device 12 include an instruction to readidentification information stored in the memory portion 110, aninstruction to make a response about necessity for charging, and thelike.

The power storage device communication portion 102 functions todemodulate the control signal transmitted from the terminal chargingdevice 12 and to modulate the control signal to be transmitted from thepower storage device 10 to the terminal charging device 12. Of thesignals, the demodulated control signal is output to the signal controlportion 103. The signal control portion 103 controls a reading orwriting operation of the memory portion 110 based on the control signal.In addition, an output of a voltage detection portion 108 which managesthe voltage of the power storage portion 106 is input to the signalcontrol portion 103, which generates a signal for making a responseabout the necessity for charging of the power storage device 10 such asdetermination of the necessity for charging.

The terminal charging device 12 transmits the power signal for chargingthe power storage device 10. When the power signal is received by theantenna 100 of the power storage device 10, it is transmitted to thecharging portion 104 through the power storage device communicationportion 102. The charging portion 104 rectifies the power signal andcharges the power storage portion 106 with electric power. Because thepower signal is an AC signal, the charging portion 104 provideshalf-wave rectification or full-wave rectification of the power signalto generate DC power. The electric power stored in the power storageportion 106 can be used by connection of a load to an output terminal105.

The amount of electric power stored in the power storage portion 106 ismanaged using the voltage detection portion 108. The voltage detectionportion 108 detects the voltage of the power storage portion 106 andmanages a charging state by the voltage. The voltage detected by thevoltage detection portion 108 is output to the signal control portion103. The signal control portion 103 outputs a charge request signal tothe power storage device communication portion 102 when the voltage isless than or equal to a specified value. When the voltage is greaterthan or equal to the specified value, the signal control portion 103outputs a charge stop signal to the power storage device communicationportion 102. The signal for making a response about the necessity forcharging of the power storage device 10 is generated by detection of theamount of voltage of the power storage portion 106, and charging poweris managed by such a method.

The terminal charging device 12 cooperates with the management server 14to control electric power supplied to the power storage device 10. Theterminal charging device 12 and the management server 14 are connectedto each other by a wired or wireless communication line. Anidentification signal, a charge enable signal, usage information, andthe like are communicated between a terminal communication portion 120of the terminal charging device 12 and a server communication portion130 of the management server 14.

The terminal communication portion 120 communicates with the powerstorage device 10 through an antenna 116. The terminal communicationportion 120 transmits an identification information request signal, acharge necessity confirming signal, or the like to the power storagedevice 10. In addition, it receives an identification signal, a chargerequest signal, and a charge non-request signal which are transmittedfrom the power storage device 10.

The terminal communication portion 120 of the terminal charging device12 outputs a signal to operate a power signal transmission portion 122when it receives a charge enable signal from the management server 14.The power signal transmission portion 122 generates a power signal byobtaining electric power from a power supply portion 128 and modulatingan output of an oscillation portion 126, which oscillates at apredetermined frequency, by a modulation portion 121. The power signalis output to the power storage device 10 using the antenna 116. In thepower signal transmission portion 122, information about chargeinitiation and termination or signals by which the power storage device10 recognizes the power signal can be communicated before and after thepower signal by modulation of the power signal. With the use of thatsignal, the operation of the charging portion 104 of the power storagedevice 10 can also be controlled. Note that although FIG. 2 shows astructure in which the antenna 116 is used to transmit both the controlsignal and the power signal, the wireless power supply system may have astructure in which the control signal and the power signal aretransmitted by separate antennas.

One example of the power signal transmitted by the power signaltransmission portion 122 is a power signal which is obtained bymodulating an AC signal into a rectangular pulse signal. When arectangular pulse signal is output for a certain period of time as thepower signal transmitted by the power signal transmission portion 122, ameasuring portion 124 counts the number of pulses to measure the amountof power supplied to the power storage device 10. Even in the case wherepulse modulation is not performed, power signals are transmittedintermittently and the measuring portion 124 measures the number oftimes the power signals are transmitted. By thus measuring the powersignal output from the power signal transmission portion 122 by themeasuring portion 124, the amount of power supplied to the power storagedevice 10 can be known.

The measured value of the measuring portion 124 is transmitted to theterminal communication portion 120 after charging is terminated. Themeasured value is further transmitted to the management server 14 and isstored in a second storage medium 134 as usage information. In addition,it may be possible to charge a user based on the usage information. Theusage information obtained by the management server 14 may betransmitted to the power storage device 10. Accordingly, the user of thepower storage device 10 can know his or her own usage information.

As described above, the wireless power supply system according to thisembodiment mode supplies electric power to the power storage device 10through cooperation of the terminal charging device 12 and themanagement server 14.

FIG. 3 shows a flow chart illustrating an operation of the wirelesspower supply system. Hereinafter, an explanation is made based on thewireless power supply system of FIG. 2, and reference will be made toboth of the diagrams.

When the terminal charging device 12 receives charge requests fromunspecified users, it is necessary to determine whether they areregistered in advance as users and permitted to charge power storagedevices. In other words, it is necessary to determine whether the powerstorage device 10 to be charged by the terminal charging device 12 isthat owned by a user who is permitted to charge a power storage device.

This determination is made based on identification information allocatedto each user. Although the identification information may be input tothe terminal charging device by a user with the use of an input medium,it is preferably recognized automatically in order to improveconvenience. The automatic recognition is preferably performed by amethod in which the identification information is stored in the powerstorage device 10 and recognized by communication between the powerstorage device 10 and the terminal charging device 12. In that case, thememory portion 110 of the power storage device 10 is provided with anidentification information storage portion 112, where the identificationinformation is stored.

In order for a user to obtain electric power in the wireless powersupply system according to this embodiment mode, a plurality of stepsneed to be performed. Each step is described below with reference toFIG. 3.

(Step 1)

First, the terminal charging device 12 operates to read theidentification information stored in the identification informationstorage portion 112 in the memory portion 110 of the power storagedevice 10. The identification information stored in the identificationinformation storage portion 112 is transmitted from the power storagedevice communication portion 102 of the power storage device 10 to theterminal communication portion 120 of the terminal charging device 12 byrequest from the terminal charging device 12. When the power storagedevice 10 does not respond to the request from the terminal chargingdevice 12 or the identification information is not communicated, it isdetermined that there is no signal, and the operation is terminated.When the terminal communication portion 120 receives the identificationinformation, the process proceeds to the next step.

(Step 2)

The terminal charging device 12 communicates with the management server14 to determine whether the identification information obtained isauthentic or not, or valid or not. The terminal charging device 12 makesan inquiry of the identification information obtained to the managementserver 14. The inquiry of the identification information is performed bytransmission of the identification information from the terminalcommunication portion 120 to the server communication portion 130 of themanagement server 14.

(Step 3)

The management server 14 determines whether the identificationinformation transmitted from the terminal charging device 12 isacceptable or not with reference to a first storage medium 132 of themanagement server 14. In the first storage medium 132, identificationinformation of users is registered. The management server 14 checks theidentification information stored in the first storage medium 132against the identification information transmitted from the terminalcharging device 12 to determine whether to permit charging or not.Accordingly, when the management server 14 does not permit charging, ittransmits a charge disable signal to the terminal charging device 12.The terminal charging device 12 which has received the charge disablesignal terminates the charging operation. When the identificationinformation is registered as authentic, a charge enable signal istransmitted to the terminal charging device 12, and the process proceedsto the next step.

(Step 4)

The terminal charging device 12 which has received the charge enablesignal transmits a signal for confirming the necessity of charging tothe power storage device 10. This is in order to prevent an unnecessaryamount of power that exceeds the capacity of the power storage portion106 from being supplied because the allowed charging amount of the powerstorage device 10 depends on the capacitance of the power storageportion 106. In other words, because the charging is to be managed bythe power storage device 10, an operation confirming whether the powerstorage device 10 needs to be charged or not becomes necessary. Thepower storage device 10 which has received a charge necessity confirmingsignal responds with a charge request signal when requesting charging ora charge non-request signal when not requesting charging. When chargingis performed, the process proceeds to Step 5, and when charging is notnecessary, the process proceeds to Step 7.

(Step 5)

When the terminal charging device 12 receives a charge request, chargingis initiated. Charging is performed with a plurality of power signals.Charging is performed through a plurality of steps in order to preventovercharging. Before the terminal charging device 12 transmits a powersignal, at the same time that it transmits a power signal, or after ittransmits a power signal, the measuring portion 124 is made to operateto measure the amount of electric power transmitted. The power signalmay be counted as described above by counting the number of pulses of apulse-modulated power signal by the measuring portion. The amount ofelectric power supplied to the power storage device 10 can be knownbased on the number of pulses counted. Transmission of the power signalcontinues for a certain period of time and is then terminated. Thelength of time it takes to transmit each power signal is set so that thepower storage portion 106 of the power storage device 10 is not fullycharged with a single power signal.

(Step 6)

In the power storage device 10 after the power signal has been received,the voltage detection portion 108 operates to monitor the amount ofvoltage of the power storage portion 106. When the amount of voltage ofthe power storage portion 106 is less than or equal to a predeterminedvalue, the voltage detection portion 108 transmits a signal to thesignal control portion 103 of the power storage device 10 so that acharge request signal can be transmitted when a charge necessityconfirming signal is received next. Alternatively, when the amount ofcharging voltage is sufficient, it transmits a signal to the signalcontrol portion 103 so as to transmit a charge non-request signal. Then,the process returns to Step 4. Note that the series of operations fromStep 4 to Step 6 is performed once or multiple number of times dependingon the amount of charge needed.

(Step 7)

The terminal charging device 12 which has received the chargenon-request signal from the power storage device 10 in step 4 terminatesthe transmission of the power signal. Then, it transmits chargeinformation measured by the measuring portion 124 from the terminalcommunication portion 120 to the management server 14.

(Step 8)

The management server 14 to which the charge information has beentransmitted performs processing for storing the charge information. Thecharge information is stored in the second storage medium 134.Generation of billing information is performed based on the informationstored in the second storage medium 134.

Next, the operations shown in FIG. 3 are described with reference toFIGS. 4 and 5. FIG. 4 illustrates transmission of information betweenthe power storage device 10, the terminal charging device 12, and themanagement server 14 and operations thereof. FIG. 5 shows timingthereof.

(1) A charging operation starts when the terminal charging device 12recognizes the power storage device 10. The terminal charging device 12transmits an instruction to read identification information to the powerstorage device 10.

(2) The power storage device 10 operates based on the instruction, andtransmits the identification information stored in the identificationinformation storage portion 112 of the memory portion 110 to theterminal charging device 12.

(3) The terminal charging device 12 transmits the identificationinformation transmitted from the power storage device 10 to themanagement server 14 to inquire whether the identification informationis that of an authentic user or not.

(4) The management server 14 checks to see whether the identificationinformation in question is that of a registered user or not withreference to data stored in the first storage medium 132 and transmitsthe result to the terminal charging device 12.

(5) The terminal charging device 12 which has received charge permissiontransmits a control signal for inquiring the necessity for charging ofthe power storage device 10.

(6) When the power storage device 10 requests charging, it responds tothe terminal charging device 12 with a charge request signal.

(7) and (8) The terminal charging device 12 which has received thecharge request from the power storage device 10 transmits a powersignal. In addition, before, after, or at the same time that the powersignal is transmitted, the measuring portion is made to operate to storethe transmission amount of the power signal.

The transmission of the power signal from the terminal charging device12 to the power storage device 10 continues for a certain period. Acharging operation of the power storage device 10 is performed with aplurality of power signals. Before, after, or at the same time that thepower signal is transmitted from the terminal charging device 12, themeasuring portion 124 is made to operate to record charge information.In addition, the number of pulses included in the pulse-modulated powersignal may be counted by the measuring portion 124.

(5) After the transmission of the power signal is terminated, theterminal charging device 12 transmits a charge necessity confirmingsignal to the power storage device 10.

(6) When the power storage device 10 requests charging, it responds tothe terminal charging device 12 with a charge request signal. Theterminal charging device 12 which has received the charge request fromthe power storage device 10 transmits a power signal.

(7) and (8) In addition, before, after, or at the same time that thepower signal is transmitted, the measuring portion 124 is made tooperate to record the transmission amount of the power signal.

In this manner, operations from (5) to (8) are repeated to provide thepower storage device 10 with a predetermined amount of power.

(9) The power storage device 10 which has received the charge necessityconfirming signal from the terminal charging device 12 transmits acharge non-request signal when charging is unnecessary.

(10) The terminal charging device 12 which has received the chargenon-request signal transmits information about the amount of electricpower that is transmitted to the power storage device 10 to themanagement server 14.

The management server 14 stores the usage information in the secondstorage medium 134. It can also generate billing information based onthe stored information.

As described above, the power storage device 10 is supplied withelectric power. By cooperation of the power storage device 10, theterminal charging device 12, and the management server 14, cordlesscharging can be performed, and convenience for users is improved. Amanager can specify a user and provide a service for charging a powerstorage device of the specified user. In this case, because anidentification number is stored in the power storage device andregistered in the management server in advance, a user does not need toperform troublesome operation in charging. The user can use the storedelectric power by connection of a load to the power storage device.

(Embodiment Mode 3)

A structure for notifying a user of a power storage device of usageinformation in Embodiment Mode 1 is described. Note that similarcomponents to those in Embodiment Mode 1 are denoted by the samereference numerals, and description of the components is omitted unlessparticularly needed.

FIG. 6 shows a structural example of a wireless power supply systemaccording to this embodiment mode. A main change from FIG. 2 is that thepower storage device 10 is provided with a display portion 115. Inaddition, the memory portion 110 is provided with a usage informationstorage portion 114 so that a user can see usage information.

The display portion 115 of the power storage device 10 can be a liquidcrystal panel, an electrochromic panel, an electroluminescent panel, adisplay panel using a contrast medium such as electronic ink, or thelike. Note that the contrast medium refers to a medium in which anelectrophoretic dispersed liquid is encapsulate in a microcapsule andwhich changes a hue or a contrast by application of a voltage. A displaypanel that uses the contrast medium has a feature of very low powerconsumption.

The display portion 115 is connected to the signal control portion 103and provided to display an operation menu screen, the amount of storedpower remaining in the power storage portion 106, the amount of powerused, and the like. By provision of the power storage device 10 with thedisplay portion 115, the user can see such information as describedabove.

Next, the operation of such a wireless power supply system is describedwith reference to FIGS. 7 and 8. FIG. 7 illustrates the transmission ofinformation between the power storage device 10, the terminal chargingdevice 12, and the management server 14 and operations thereof. FIG. 8shows timing thereof. Note that the operations (1) to (10) are similarto those in Embodiment Mode 1, so that description thereof is omitted.

The management server 14 which has received the charge informationtransmitted from the terminal charging device 12 stores the usageinformation in the second storage medium 134. It can also generatebilling information based on the usage information.

(11) In order to notify a user of this information, the usageinformation, the billing information, and the like is transmitted asaccumulated charge information to the terminal charging device 12. Thecontent of the usage information or the like may be transmitted everytime usage is generated, usage information for a certain period may becollectively transmitted, or cumulative usage information for a certainperiod may be transmitted, any of which may be selected as appropriate.

(12) The terminal charging device 12 transmits the usage information andthe billing information that is transmitted as the accumulated chargeinformation from the management server 14 to the power storage device10.

(13) The power storage device 10 receives the information.

The information received is stored in the usage information storageportion 114 of the memory portion 110. The usage information stored inthe usage information storage portion 114 can be displayed on thedisplay portion 115 so that it can be seen by the user.

As described above, the power storage device 10 can be supplied withelectric power; in addition, a user can know the usage information suchas the amount of power, the date and time of usage, or the like of thesupply from the terminal charging device 12, the billing information,and the like. Accordingly, convenience for a user can be increased. Amanager can provide a service for encouraging a user in usage of thissystem or alerting a user so that the user does not receive the supplyof an excessive amount of electric power.

(Embodiment Mode 4)

An information distribution system which is structured using thewireless power supply system according to the present invention isdescribed with reference to FIG. 9. Note that similar components tothose in Embodiment Mode 1 or 3 are denoted by the same referencenumerals, and description of the components is omitted unlessparticularly needed.

FIG. 9 shows a structural example of a wireless power supply systemaccording to this embodiment mode. The management server 14 has a thirdstorage medium 180, which stores information to be provided for users,in addition to the server communication portion 130, the first storagemedium 132 which stores user identification information, and the secondstorage medium 134 which stores usage information. The information to beprovided for users includes entertainment information for users, such asmusic information, image information, movie information, or computerprogram information, and information useful for users, such as maps orroute information. The terminal charging device 12 has a similarstructure to that of Embodiment Mode 3. The terminal communicationportion 120 communicates with the server communication portion 130 ofthe management server 14 and controls the operation of the power signaltransmission portion 122.

A memory card 20 with a power storage device has the memory portion 110including the identification information storage portion 112, the usageinformation storage portion 114, and a storage portion 182 of theinformation provided for a user; the antenna 100 which receives electricwaves transmitted from the terminal charging device; and the powerstorage portion 106 which stores the electric waves received by theantenna 100 as electric power and supplies the electric power for memoryretainment to the memory portion 110. The storage portion 182 of theprovided information stores the information transmitted from theinformation to be provided for users which is stored in the thirdstorage medium 180 of the management server 14.

The storage portion 182 of the provided information includes a volatilememory. The volatile memory includes a dynamic RAM, a static RAM, or thelike. The memory card 20 with a power storage device retains informationstored in the storage portion 182 of the provided information for acertain period. Therefore, electric power necessary for the volatilememory to retain information is supplied from a memory power supplycircuit 188 using the power storage portion 106. The volatile memoryretains information while electric power is supplied from the memorypower supply circuit 188.

The information stored in the memory portion 182 of the providedinformation can be used by connection of the memory card 20 with a powerstorage device to an external device such as a reproducer. An outputterminal 186 is a terminal that is to be connected to an externaldevice, and the information of the storage portion 182 of the providedinformation is output through an output interface 184.

The memory card 20 with a power storage device can store the informationof the storage portion 182 of the provided information in the memoryportion 110 while electric power is stored in the power storage portion106. For example, when the information to be provided for users isprovided from the management server 14 to the memory card 20 with apower storage device, a certain amount of electric power is suppliedfrom the terminal charging device 12. When a user desires to extend thelength of time the provided information is available, the user transmitsa request to the terminal charging device 12 so that electric power issupplied to the memory card 20 with a power storage device. At thistime, the terminal charging device 12 and the management server 14 maycooperate with each other to charge a bill for the extension of theperiod during which information is available.

Next, a method for distributing information, of which the period duringwhich it is effective is limited, by using the wireless power supplysystem according to this embodiment mode is described.

A user who desires to obtain the information to be provided for usersperforms a procedure for receiving a supply of power from the terminalcharging device 12 in order to charge the memory card 20 with a powerstorage device. This procedure is similar to Step 1 to Step 7illustrated in FIG. 3, and description thereof is omitted. In otherwords, at a stage where the process proceeds up to Step 7 and chargingof the power storage portion 106 is completed, a procedure for obtainingthe information to be provided for users is performed. Hereinafter, theprocedure is described with reference to FIG. 10.

(Step 9)

When the terminal charging device 12 notifies the management server 14that charging is completed, the information to be provided for users istransmitted from the third storage medium 180 of the management server14. The transmitted information to be provided for users is stored inthe storage portion 182 of the provided information of the memory card20 with a power storage device through the terminal charging device 12.The management server 14 operates to update the usage information in thesecond storage medium 134. In other words, the fact that a specific userhas obtained the information to be provided for users is stored, or newbilling information is generated.

(Step 10)

Because the storage portion 182 of the provided information of thememory card 20 with a power storage device includes a volatile memory,it requires continuous power supply from the power storage portion 106to retain the information for a user. In this case, because the power ofthe power storage portion 106 decreases over time, the voltage detectionportion 108 needs to periodically monitor the voltage of the powerstorage portion 106. In addition, when the voltage of the power storageportion 106 is decreased and it is determined that additional chargingis necessary, a user determines whether retainment of the informationfor the user stored in the memory portion 182 of the providedinformation is desired or not. When the user desires to extend thelength of time the information for the user is available, the processreturns to Step 1 and a charging operation is initiated. Accordingly,the length of time the information for the user is available can beextended. When the user does not desire to extend the length of time theinformation for the user is available, the information for the user islost when the power of the power storage portion 106 is used up.

In this manner, a provider of information for a user can provide a userwith information only for a limited length of time. In addition, a userwho desires extension can receive a supply of electric power forretaining the information for the user stored in the storage portion 182of the information provided for the user to the memory card 20 with apower storage device and can be charged for the extension.

FIGS. 11A and 11B show examples of application of the memory card 20with a power storage device. FIG. 11A shows a cellular phone, which is atypical example of a portable electronic device. This cellular phone hasa chassis 189, a display portion 190, an operation key 192, and thelike. The cellular phone has a memory card slot 193, and by insertion ofthe memory card 20 with a power storage device into the memory card slot193, information stored in the memory portion where the memory isretained by the power storage device can be utilized. Such informationincludes data such as phone numbers, maps, images, and music data, andthe like.

FIG. 11B shows a digital player, which is another typical example of aportable electronic device. The digital player shown in FIG. 11B has achassis 196, a display portion 198, an operation portion 202, a receiver204, and the like. The digital player has a memory card slot 199, and byinsertion of the memory card 20 with a power storage device into thememory card slot 199, information stored in the memory portion where thememory is retained by the power storage device can be utilized. Suchinformation includes images, music data, and the like.

In this manner, by use of a power storage device as a memory retainingpower source of a volatile memory according to this embodiment mode, aninformation provider can manage information provided for a user so thatthe information is available for a certain period. Accordingly,copyright and the like can be protected, and use of a copyright can alsobe billed.

(Embodiment Mode 5)

The power storage device according to the present invention has at leasta memory portion which stores identification information, a powerstorage portion, and an antenna which receives a power carrier wave anda communication signal. An example of such a power storage device isdescribed with reference to drawings. This embodiment mode describes anexample of a power storage device combining a first structure 136provided with an antenna, a second structure 138 provided with a powerstorage portion, and a third structure 140 provided with a circuitportion including a communication portion, a signal control portion, acharging portion, a memory portion, and the like (hereinafter referredto as a power storage device control circuit), with reference to FIGS.12A to 13B. Note that FIGS. 12A to 12C are plan views of the powerstorage device. FIGS. 13A and 13B are cross-sectional views taken alonga section line A-B and a section line C-D, respectively.

FIG. 12A shows the first structure 136 provided with an antenna 142. Thefirst structure 136 is fowled of an insulating material such as aninsulating plate or an insulating film. An applicable material of theinsulating plate or the insulating film is plastic such as PET(polyethylene terephthalate), PEN (polyethylene naphthalate), PES(polyether sulfone), polypropylene, polypropylene sulfide,polycarbonate, polyetherimide, polyphenylene sulfide, polyphenyleneoxide, polysulfone, polyphthalamide, acrylic, or polyimide, glass, anonwoven fabric, a paper material, or the like.

The antenna 142 is formed by a printing method, a plating method, or thelike using a low-resistance metal material such as copper, silver, oraluminum. The antenna 142 is formed on either or both sides of the firststructure 136. By forming the antenna 142 using both sides of the firststructure 136, the length or area of the antenna can be increased, sothat gain can also be increased. FIG. 12A shows the antenna 142 in acoil shape, which is suitable for the case of employing a magnetic fieldmethod. In the case of employing an electric field method (for example,a UHF band (860 to 960 MHz band), a 2.45 GHz band, or the like), theshape, such as the length, of a conductive layer functioning as anantenna may be appropriately set in consideration of the wavelength ofan electromagnetic wave used for signal transmission. In this case, amonopole antenna, a dipole antenna, a patch antenna, or the like may beformed.

The second structure 138 and the third structure 140 are arranged inaccordance with an antenna terminal 144 of the first structure 136. FIG.12B is a plan view of the second structure 138, and FIG. 12C is a planview of the third structure 140 provided with the power storage devicecontrol circuit. The second structure 138 and the third structure 140provided with the power storage device control circuit preferably haveapproximately the same dimension. Alternatively, the third structure 140provided with the power storage device control circuit may have asmaller dimension than the second structure 138. The third structure 140provided with the power storage device control circuit has a powerstorage device communication portion, a signal control circuit, acharging circuit, a memory portion, and the like as shown in FIG. 2.

Next, the details of a connection structure of the second structure 138and the third structure provided with the power storage device controlcircuit are described with reference to FIGS. 13A and 13B. FIG. 13Ashows a cross-sectional view taken along a section line A-B. The firststructure 136 and the third structure 140 provided with the powerstorage device control circuit are connected to each other by a throughelectrode 146 formed in the second structure 138. These are fixed by anadhesive 154. The second structure 138 is fowled by stacking layers eachincluding a dielectric layer 158 and a capacitor electrode 160 so as tobe engaged with each other. The power storage portion is fowled by thusstacking the dielectric layers 158 and the capacitor electrodes 160. Inother words, the second structure 138 forms the power storage portion.

The through electrode 146 which penetrates the dielectric layers 158 isan electrode which connects the antenna terminal 144 and the thirdstructure 140 provided with the power storage device control circuit. Inthe third structure 140 provided with the power storage device controlcircuit, a connection electrode 150 connected to the antenna terminal144 and a capacitor portion connection electrode 152 connected to thecapacitor electrode 160 are formed. A sealing material 156 is providedto cover the whole in order to protect the second structure 138 and thethird structure 140 provided with the power storage device controlcircuit.

The dielectric layer 158 is formed by coating a substrate with a ceramicpaste including a binder compound, a plasticizer, and an organic solventin a ceramic material such as barium titanate (BaTiO₃), strontiumtitanate (SrTiO₃), or a lead-based perovskite compound material. Overthat, an electrode paste selected from copper, a copper alloy, nickel, anickel alloy, silver, a silver alloy, tin, and a tin alloy is printed toform the capacitor electrode 160. Note that when the through electrode146 is formed, an opening is formed in a corresponding position. Afterthese are dried, they are divided into a predetermined size, and aplurality of layers are stacked so that the capacitor electrodes 160alternately engage with each other. This is sandwiched betweenprotective layers 162 formed of a ceramic material and subjected todebindering, baking, and heat treatment; thus, the power storage portionis formed.

In FIGS. 13A and 13B, the dielectric layer 158 and the capacitorelectrode 160 can each be formed with a thickness of 1 μm to 10 μm byusing nano particles. Accordingly, a total thickness of five stackeddielectric layers 158 each having a thickness of 2 μm is 10 μm. Inaddition, even a total thickness of ten stacked dielectric layers 158each having a thickness of 1 μm is 10 μm.

FIG. 13B shows a cross-sectional view taken along a section line C-D,which shows a structure of the capacitor electrode 160 and the capacitorportion connection electrode 152 of the third structure 140 providedwith the power storage device control circuit. In the second structure138, a capacitor external electrode 148 formed at the periphery issubjected to nickel plating, tin plating, or the like. A connection ofthe capacitor external electrode 148 and the capacitor portionconnection electrode 152 can be achieved by the adhesive 154.

As described above, the power storage device combining the firststructure 136 provided with the antenna, the second structure 138provided with the power storage portion, and the third structure 140provided with the power storage device control circuit is obtained. Withthe use of the second structure 138 formed of ceramic or the like, therigidity of the power storage device can be increased. Accordingly, evenwhen the power storage device having the third structure 140 providedwith the power storage device control circuit is thinned, strength canbe maintained and required function can also be maintained.

Next, an example of a power storage device having a plurality ofantennas is described. An example of a power storage device combiningthe first structure 136 provided with the antenna, the second structure138 provided with the power storage portion, the third structure 140provided with the power storage device control circuit, and a ceramicantenna 164 is described with reference to FIGS. 14A to 15B. Note thatFIGS. 14A to 14D are plan views of the power storage device, and FIGS.15A and 15B are cross-sectional views taken along a section line E-F anda section line G-H, respectively.

FIG. 14A shows a plan view of the power storage device. The firststructure 136 is provided with the antenna 142. The antenna 142 can bechanged in shape depending on frequency band used for transmission andreception of electric waves. In the power storage device, the secondstructure 138, the third structure 140 provided with the power storagedevice control circuit, and the ceramic antenna 164 are arranged inaccordance with the antenna terminal 144.

FIG. 14B is a plan view of the second structure 138; FIG. 14C is a planview of the third structure 140 provided with the power storage devicecontrol circuit; and FIG. 14D is a plan view of the ceramic antenna 164.The second structure 138, the third structure 140 provided with thepower storage device control circuit, and the ceramic antenna 164preferably have approximately the same dimension. Alternatively, thethird structure 140 provided with the power storage device controlcircuit may have a smaller dimension than the second structure 138 andthe ceramic antenna 164.

The second structure 138 is fowled of a ceramic material. The secondstructure 138 is provided with the through electrode 146 and thecapacitor external electrode 148. The third structure 140 provided withthe power storage device control circuit is provided with the connectionelectrode 150 connected to the antenna terminal 144, the capacitorportion connection electrode 152 connected to the capacitor externalelectrode 148, and the ceramic antenna connection electrode 153connected to the ceramic antenna 164.

FIG. 15A shows a cross-sectional view taken along a section line E-F. Inthe second structure 138, a power storage portion is fowled of a ceramicmaterial. A structure including the through electrode 146 connecting theantenna terminal 144 of the first structure 136 and the connectionelectrode 150 of the third structure 140 provided with the power storagedevice control circuit is similar to that shown in FIG. 13A. On a backside of the third structure 140 provided with the power storage devicecontrol circuit, the ceramic antenna 164 is arranged. The secondstructure 138 and the ceramic antenna 164 sandwiching the thirdstructure 140 provided with the power storage device control circuitalso function as protective layers.

FIG. 15B shows a cross-sectional view taken along a section line G-H,and shows a connection structure of the third structure 140 providedwith the power storage device control circuit and the ceramic antenna164. The ceramic antenna 164 includes a ground body 170 on one side of adielectric body 168 (on the third structure 140 side) and a reflector172 on the other side. The third structure 140 provided with the powerstorage device control circuit is provided with the ceramic antennaconnection electrode 153, to which the ground body 170 and apower-feeding body 166 are connected. The reflector 172 may be providedwith a slit for increasing directivity. The reflector 172 and thepower-feeding body 166 are arranged with a gap therebetween and arecapacitively coupled.

In this power storage device, the antenna 142 formed in the firststructure 136 and the ceramic antenna 164 are used as power-feedingantennas, and the power storage portion formed in the second structure138 is charged. The power storage portion includes the dielectric layers158 and the capacitor electrodes 160. By stacking a plurality of layerseach including the dielectric layer 158 and the capacitor electrode 160,a large capacitor can be formed. In this case, the power storage portioncan be efficiently charged by using electromagnetic waves with differentfrequencies to be received by the antenna 142 and the ceramic antenna164. In other words, the band of electromagnetic waves received forcharging the power storage portion can be widened. In this case, thedielectric layer 158 and the capacitor electrode 160 can each be formedwith a thickness of 1 μm to 10 μm by using nano particles. Accordingly,a total thickness of five stacked dielectric layers 158 each having athickness of 2 μm is 10 μm. In addition, even a total thickness of tenstacked dielectric layers 158 each having a thickness of 1 μm is 10 μm.

As described above, the power storage device combining the firststructure 136 provided with the antenna, the second structure 138provided with the power storage portion, the third structure 140provided with the power storage device control circuit, and the ceramicantenna 164 is obtained. With the use of the second structure 138 fowledof ceramic or the like and the ceramic antenna 164, reductions in sizeand weight and an increase in rigidity of the power storage device canbe achieved. Such a power storage device can be applied to any of thewireless power supply systems of Embodiment Modes 1 to 4.

(Embodiment Mode 6)

This embodiment mode describes a structure of a power storage device andan example of its application. The power storage device exemplified hereincludes a first structure provided with an antenna, a second structureprovided with a capacitor portion, and a third structure provided with apower storage device control circuit, similarly to Embodiment Mode 5.

FIG. 16 shows a planar structure of the power storage device accordingto this embodiment mode. Cross-sectional views taken along a sectionline J-K and a section line L-M of the above drawing are shown in FIGS.17A and 17B, respectively. The description below is made with referenceto these diagrams. Note that the section line J-K is provided to show aconnection structure of the antenna and the power storage device controlcircuit, and the section line L-M is provided to show a connectionstructure of the power storage portion and the power storage devicecontrol circuit.

The first structure 136 is provided with the antenna 100. The antenna100 is formed over one surface of the first structure 136. On a sideopposite to the surface of the first structure 136, the second structure138 provided with the power storage portion is formed. On a back side ofthe second structure 138, the third structure 140 provided with thepower storage device control circuit is formed.

The antenna 100 provided in the first structure 136 is connected to thepower storage device control circuit formed in the third structure 140by the through electrode 146 of the second structure 138. The antenna100 can be formed on either or both sides of the first structure 136.The first structure 136 may be provided with a wiring which penetratesthe first structure 136 in order to connect the antenna 100 to thethrough electrode 146. In order to protect the antenna 100, a protectivefilm 176 may be provided over the surface of the first structure 136.The protective film 176 can be applied to various applications when itssurface is formed of a bioinert material such as diamond-like carbon,silicon nitride, or alumina.

The capacitor portion fat fined in the second structure 138 storeselectric power which is received by the antenna. The capacitor externalelectrode 148 is fowled over a side end surface of the second structure138 and is extended so as to be connected to the power storage devicecontrol circuit. Detailed structures of these are similar to those inEmbodiment Mode 5.

The power storage device preferably has an antenna with high sensitivityin order to efficiently receive electromagnetic waves and store electricpower. A multiband antenna may be used so as to be able to receiveelectromagnetic waves of a wide frequency band. Alternatively, aplurality of antennas may be combined. FIG. 16 shows an example of acombination of a magnetic field antenna and an electric field antenna.The antenna 100 can be used to receive electric waves of ahigh-frequency band (electromagnetic waves with a frequency of 1 MHz to30 MHz) and a very high-frequency band (electromagnetic waves with afrequency of 30 MHz to 300 MHz), and an antenna 101 can be used toreceive electric waves of an ultra high-frequency band (electromagneticwaves with a frequency of 0.3 GHz to 3 GHz). When an antenna is formedso as to be able to receive electric waves of a wide frequency band, itis possible to respond to the cases where different frequencies are usedfor chargers. For example, it is also possible to flexibly respond tothe case where the power storage device is used in differentenvironments such as in different countries or areas.

A region of the power storage device, other than a surface where theantenna is formed, is preferably structured not to leak electromagneticwaves or structured to absorb electromagnetic waves. Therefore, anelectric wave absorption material 174 is provided. The electric waveabsorption material 174 is provided to cover side surfaces of the secondstructure 138 and side surfaces and a bottom surface of the thirdstructure 140. In other words, it is provided to cover surfaces otherthan the surface of the first structure 136 where the antenna 100 isformed. As the electric wave absorption material 174, various materialscan be used; for example, a base material in which an electric waveabsorption material is dispersed can be used. The base material may bean industrially-used resin material or plastic material. The electricwave absorption material may be carbon, ferrite, or the like. Carbon isa cluster of carbon atoms, which is called by different names such asgraphite, carbon black, amorphous carbon, and the like. Ferrite isrepresented by chemical formula, MO.Fe₂O₃, and M is generally Zn, Cd,Fe, Ni, Cu, Co, Mg, or the like. In this manner, by providing theelectric wave absorption material 174 in the power storage device, thepower storage device can be safely used even when, for example, embeddedin a living body.

Each of FIGS. 18A and 18B shows a mode of using the power storage deviceshown in FIGS. 17A and 17B embedded in a living body or a solid. Forsuch an application, the power storage device according to the presentinvention can be applied to a power supply portion of an electricalstimulation generation device for maintaining a function of an internalorgan by application of electrical stimulation to a living body.

FIG. 18A shows a state where the power storage device 10 is provided onan inner side than a nonmetal surface 178. The nonmetal surface 178 isfowled of a skin of a living body, a nonmetal material such as plasticforming a chassis of an electronic device, a piece of paper, a nonwovenfabric, a clothing material, or the like. Of the power storage device10, a surface where the antenna 100 is formed is exposed and the otherpart is covered with the electric wave absorption material 174.Electromagnetic waves emitted from the antenna 118 of the terminalcharging device 12 which is positioned to face the nonmetal surface 178are transmitted through the nonmetal surface 178 and absorbed by theantenna 100 of the power storage device 10. In this case, by using aparabolic antenna as the antenna 118 of the terminal charging device 12as shown in FIG. 18B, the directivity of electromagnetic waves isimproved. In other words, when the power storage device is embedded in aliving body, an unnecessary region thereof can be prevented from beingexposed to electromagnetic waves. This applies to the case where thepower storage device 10 is provided in a chassis of an electronicdevice, and the electronic device can be prevented from malfunctioningdue to the influence of electromagnetic waves on the other part.

As described above, the power storage device combining the firststructure 136 provided with the antenna, the second structure 138provided with the power storage portion, the third structure 140provided with the power storage device control circuit, and the ceramicantenna 164 is obtained. With the use of the second structure 138 fowledof ceramic or the like and the ceramic antenna 164, reductions in sizeand weight and an increase in rigidity of the power storage device canbe achieved. Such a power storage device can be applied to any of thewireless power supply systems of Embodiment Modes 1 to 4.

This application is based on Japanese Patent Application Serial No.2006-316750 filed with Japan Patent Office on Nov. 24, 2006, the entirecontents of which are hereby incorporated by reference.

1-13. (canceled)
 14. A wireless power supply system comprising: a serverconfigured to determine whether a first identification information isvalid or not with reference to a second identification information, andto send a signal of an information that the first identificationinformation is valid; and a charging device configured to wirelesslytransmit an electric power after receiving the signal, wherein the firstidentification information is transmitted from the charging device, andwherein the second identification information is stored in the server.15. The wireless power supply system according to claim 14, wherein thecharging device is connected to the server via a wireless line.
 16. Thewireless power supply system according to claim 14, wherein the servercomprises a first storage medium configured to store the secondidentification information, and wherein the charging device comprises: acommunication portion configured to communicate with the server; anantenna configured to transmit with the electric power; and a measuringportion configured to measure an amount of the electric power.
 17. Thewireless power supply system according to claim 16, wherein the serverfurther comprises a second storage medium to store usage information ofthe electric power.
 18. The wireless power supply system according toclaim 14, wherein the electric power is transmitted to a power storagedevice comprising the first identification information.
 19. The wirelesspower supply system according to claim 14, wherein the electric power istransmitted to a memory card with a power storage device comprising thefirst identification information.
 20. The wireless power supply systemaccording to claim 18, wherein the power storage device is embedded in aliving body or a solid.
 21. The wireless power supply system accordingto claim 14, wherein the electric power is transmitted to an electricalstimulation generation device comprising the first identificationinformation, and wherein the electrical stimulation generation deviceconfigured to maintain a function of an internal organ by application ofelectrical stimulation to a living body.
 22. The wireless power supplysystem according to claim 18, wherein the power storage devicecomprises: a memory portion configured to store the first identificationinformation; an antenna configured to receive the electric power fromthe charging device; and a power storage portion configured to store theelectric power.
 23. A wireless power supply method for managing powersupply, comprising the steps of: reading a first identificationinformation; transmitting the first identification information from acharging device to a server comprising a second identificationinformation; receiving a first signal from the server when the firstidentification information is valid with reference to the secondidentification information; and wirelessly transmitting an electricpower after receiving the first signal.
 24. The wireless power supplymethod according to claim 23, further comprising the steps of: measuringan amount of the electric power; and transmitting a information of theamount of the electric power to the server.
 25. The wireless powersupply method according to claim 24, further comprising the step ofreceiving a charge non-request signal before transmitting theinformation of the amount of the electric power.
 26. The wireless powersupply method according to claim 23, further comprising the step of:receiving an accumulated charge information from the server, wherein theaccumulated charge information comprise an usage information and abilling information.
 27. The wireless power supply method according toclaim 23, wherein the charging device is connected to the server via awireless line.
 28. The wireless power supply method according to claim23, further comprising the step of: receiving a second signal from theserver when the first identification information is not valid withreference to the second identification information, wherein the electricpower is not wirelessly transmitted when the server transmits the secondsignal.